Preparation of Alumina Binder-Added PtSnNa/AlSBA-15 Catalyst for Propane Dehydrogenation 被引量：1

Preparation of Alumina Binder-Added PtSnNa/AlSBA-15 Catalyst for Propane Dehydrogenation

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摘要 Abstract： The present article compares the propane dehydrogenation performance of alumina binder-added PtSnNa/ A1SBA-15 catalysts prepared via three different procedures in comparison with the performance of a binder-free PtSnNa/ AISBA-15 catalyst. All these catalysts have been investigated by reaction tests and some physico-chemical characterizations such as BET, H2 chemisorption, catalytic grain crushing strength, NHa-TPD and TPO analyses. Test results showed that the addition of alumina binder could enhance the mechanical strength of catalyst evidently. Moreover, the different preparation procedures not only modified the characteristics of both acid and metal functions but also affected the coke deposition on the catalysts. Among these catalysts studied, the catalyst prepared by impregnation followed by the agglomeration of alumi- na binder had exhibited the highest catalytic activity and stability compared with other catalyst samples undergoing different preparation procedures. The possible reason may be attributed to the highest metallic dispersion and the strong interactions among Pt, Sn and the support. The present article compares the propane dehydrogenation performance of alumina binder-added PtSnNa/ AlSBA-15 catalysts prepared via three different procedures in comparison with the performance of a binder-free PtSnNa/AlSBA-15 catalyst. All these catalysts have been investigated by reaction tests and some physico-chemical characterizations such as BET, H2 chemisorption, catalytic grain crushing strength, NH3-TPD and TPO analyses. Test results showed that the addition of alumina binder could enhance the mechanical strength of catalyst evidently. Moreover, the different preparation procedures not only modified the characteristics of both acid and metal functions but also affected the coke deposition on the catalysts. Among these catalysts studied, the catalyst prepared by impregnation followed by the agglomeration of alumina binder had exhibited the highest catalytic activity and stability compared with other catalyst samples undergoing different preparation procedures. The possible reason may be attributed to the highest metallic dispersion and the strong interactions among Pt, Sn and the support.

作者 Zhang Peixin Zhou Yuming Duan Yongzheng Zhang Yiwei Sheng Xiaoli

机构地区 School of Chemistry and Chemical Engineering Geological Survey of Jiangsu Province

出处《China Petroleum Processing & Petrochemical Technology》 SCIE CAS 2013年第1期25-31,共7页 中国炼油与石油化工（英文版）

基金 the National Nature Science Foundation of China(50873026,and21106017) the Production and Research Prospective Joint Research Project(BY2009153) the Science and Technology Support Program(BE2008129) of Jiangsu Province of China Specialized Research Fund for the Doctoral Program of Higher Education of China(20100092120047) for financial supports

关键词 A1SBA-15 BINDER preparation procedure propane dehydrogenation alumina. 催化剂丙烷脱氢粘合剂氧化铝制备性能比较机械强度金属功能

分类号 TE624.9 [石油与天然气工程—油气加工工程]

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参考文献3

1Yongzheng Duan,Yuming Zhou,Yiwei Zhang,Xiaoli Sheng,Shijian Zhou,Zewu Zhang.Effect of aluminum modification on catalytic properties of PtSn-based catalysts supported on SBA-15 for propane dehydrogenation[J].Journal of Natural Gas Chemistry,2012,21(2):207-214. 被引量：6
2林励吾,杨维慎,贾继飞,徐竹生,张涛,范以宁,寇元,沈俭一.Surface structure and reaction performances of highly dispersed and supported bimetallic catalysts[J].Science China Chemistry,1999,42(6):571-580. 被引量：4
3Duan Yongzheng,Zhou Yuming,Zhang Yiwei,Sheng Xiaoli,Xue Mengwei.Propane Dehydrogenation on PtSnNa/AlSBA-15 Catalyst:Influence of Tin as a Promoter[J].China Petroleum Processing & Petrochemical Technology,2012,14(1):37-45. 被引量：4

二级参考文献72

1Salmones J, Wang J A, Galicia J A, et al. H2 reduction behaviors and catalytic performance of bimetallic tin-modified platinum catalysts for propane dehydrogenation[J]. J Mol Catal A, 2002, 184(1/2): 203-213.
2Bocanegra S A,Yanez M J, Scelza O, et al. Effect of the synthesis method of MgAl2O4 and of Sn and Pb addition to platinum catalysts on the behavior in n-butane dehydrogenation[J]. Ind Eng Chem Res, 2010, 49(9): 4044-4054.
3Bocanegra S A, de Miguel S R, Borbath I, et al. Behavior of bimetallic PtSn/Al2O3 catalysts prepared by controlled surface reactions in the selective dehydrogenation of butane[J]. J Mol. Catal A, 2009, 301(1/2): 52-60.
4Santhosh K M, Chen D, Holmen A, et al. Dehydrogenation of propane over Pt-SBA-15 and Pt-Sn-SBA-15: Effect of Sn on the dispersion of Pt and catalytic behavior[J]. Catal Today, 2009, 142(1/2): 17-23.
5Kustrowski P, Segura Y, Chmielarz L, et al. VOx supported SBA- 15 catalysts for the oxidative dehydrogenation of eth- ylbenzene to styrene in the presence of N2O[J]. Catal Today, 2006, 114(2-3): 307-313.
6Larsson M, Hulten M, Blekkan E A, et al. The effect of reaction conditions and time on stream on the coke formed during propane dehydrogenation [J]. J Catal, 1996, 164(1): 44-53.
7Volter J, Lietz G, Uhlemann M, Hermann M. Conversion of cyclohexane and n-heptane on Pt-Pb/Al2O3 bimetallic cata- lysts [J]. J Catal,1981, 68(1): 42-50.
8Clarke J K A. Selectivity in catalysis by alloys[J]. Chem Rev, 1975, 75(3): 291-305.
9Muller A C, Engelhard P A, Weisang J E. Surface study of platinum-tin bimetallic reforming catalysts[J]. J Catal, 1979, 56(1): 64-72.
10Beltramini J, Trimm D L. Catalytic reforming of n-heptane on platinum, tin and platinum-tin supported on alumina[J]. Appl Catal, 1987, 31(1):113-118.

共引文献10

1刘丽花,房德仁,刘波,秦玉武,薛建成,任万忠.异丁烷催化脱氢研究进展[J].工业催化,2012,20(12):9-14. 被引量：5
2Zhang Peixin,Zhou Yuming,Duan Yongzheng,Zhang Yiwei,Sheng Xiaoli.Influence of Alumina Content on Catalytic Performance of PtSn/Al_2O_3/SBA-15 Catalysts for Propane Dehydrogenation[J].China Petroleum Processing & Petrochemical Technology,2012,14(4):9-16. 被引量：4
3Huang Li,Zhou Shijian,Zhou Yuming,Zhang Yiwei,Xu Jun,Wang Li.Influence of the Alkali Treatment of HZSM-5 Zeolite on Catalytic Performance of PtSn-Based Catalyst for Propane Dehydrogenation[J].China Petroleum Processing & Petrochemical Technology,2013,15(2):11-18. 被引量：2
4罗沙,吴楠,周波,何松波,邱介山,孙承林.氧化铝载体对Pt-Sn-K/γ-Al2O3催化剂上异丁烷脱氢性能的影响[J].燃料化学学报,2013,41(12):1481-1487. 被引量：16
5马爱增.中国催化重整技术进展[J].中国科学：化学,2014,44(1):25-39. 被引量：51
6刘乔,董秀芹,余英哲,张敏华.丙烷无氧脱氢制丙烯工艺和催化剂的研究进展[J].石油化工,2014,43(6):713-720. 被引量：11
7刘东升.模拟移动床上Pt-Sn-K/γ-Al_2O_3丙烷脱氢催化剂的制备及性能研究[J].工业催化,2016,24(10):56-59. 被引量：4
8Wang Bo.Fabrication of the Core-Shell Structured ZSM-5@Mg(Al)O and Its Catalytic Application in Propane Dehydrogenation[J].China Petroleum Processing & Petrochemical Technology,2018,20(1):25-36.
9张晓松,马健云,刘坚,宋卫余.丙烷直接脱氢制丙烯分子筛催化剂的研究进展[J].现代化工,2020,40(12):33-38. 被引量：1
10张雨宸,张耀远,吴芹,史大昕,陈康成,黎汉生.丙烷脱氢用高稳定性Pt基催化剂研究进展[J].化工进展,2022,41(9):4733-4753. 被引量：7

同被引文献14

1陈姣,张爱民,李晓鸥,秦永航,李文深.石油产品非加氢脱氮技术进展[J].精细石油化工进展,2007,8(11):37-44. 被引量：11
2Cheng Xingguo,Zhao Ting, Fu Xingguo, et al. Identification of nitrogen compounds in RFCC diesel oil by mass speetrome- try[J]. Fuel Processing Technology, 2004,85 (9) : 1463- 1472.
3Chen Xiaobo, Li Teng, Liu Yibin, et al. Characterization of ni- trogen compounds in vacuum residue and their sructure com- parison with coker gas oil [J]. China Petroleum Processing and Petrochemical Technology,2014,16(3) :33-41.
4Khodakov A Y, Bechara R, Griboval C A. Fischer-Tropsch synthesis over silica supported cobalt catalysts: Mesoporous structure,versus cobalt surface density[J]. Applied Catalysis A&General,2003,254(2) :273-288.
5Wang Ye, Zhang Qinghong, Yoshihiko Ohishi, et al. Synthe- sis of V-MCM 41 by template-ion exchange method and its catalytic properties in propane oxidative dehydrogenation[J]. Catalysis Letters,2001,72(3/4) :215-219.
6Melero J A, Iglesias J, Arsuaga J M, et al. Synthesis, charac- terization and catalytic activity of highly dispersed Mo-SBA- 15 [J]. Applied Catalysis A: General, 2007,331 (1) : 84-94.
7Chen Yangying, Huang Yanlei,Xiu Jinghai, et al. Direct syn thesis, characterization and catalytic activity of titanium-sub- stituted SBA-15 mesoporous molecular sieves [J]. Applied Catalysis A & General, 2004,273 (1/2) : 185-191.
8Martin C,Malet P,Solana G,et al. Structural analysis of sili ca-supported tungstates[J]. J Phys Chem B, 1999,102 (15) :2759-2768.
9赵秦峰,陈胜利,高金森,徐春明,李东瑜,赵震.W-SBA-15的直接合成及其对2-丁烯与乙烯歧化制丙烯反应的催化性能[J].化工学报,2009,60(1):75-82. 被引量：7
10刘兴利,王榕,李永红.吸附法脱除烷基化用汽油中的碱性氮化物[J].离子交换与吸附,2009,25(1):45-51. 被引量：14

引证文献1

1唐磊,纪桂杰,沈健.W-SBA-15的制备及其吸附脱氮性能研究[J].石油炼制与化工,2015,46(8):76-80. 被引量：4

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1孙明珠,刘珊珊,张兵,吴永红,傅承碧.采用吸附固定床脱除正己烷中的吡啶[J].石油化工,2017,46(4):471-476. 被引量：1
2洪新,李云赫,袁加成,赵永华,唐克.变色硅胶吸附脱除模拟柴油中各种碱性氮化物[J].燃料化学学报,2018,46(3):298-304. 被引量：10
3洪新,李云赫,高畅,范博,庞宇莹,唐克.ZSM-5分子筛脱除模拟燃料中苯胺或吡啶的吸附行为[J].石油化工,2018,47(12):1362-1368. 被引量：2
4唐克,高畅,潘政华,李云赫,洪新.硅胶负载杂多酸吸附脱除模拟柴油中的苯胺及其动力学研究[J].精细石油化工,2019,36(2):49-55. 被引量：2

1S.REVATHI,M.Esther Leena PREETHI,D.MANIKANDAN,D.DIVAKAR,A.Valentine RUPA,T.SIVAKUMAR.12-钨磷酸在AlSBA-15上的固定化及其乙酰化催化活性(英文)[J].催化学报,2008,29(12):1202-1210. 被引量：2
2孔令文,张松茂.应用HES高效选粉机生产高细高铝水泥[J].中国建材科技,1998(4):25-27.
3郭宏武,何正凯,等.HES高效选粉机在矿渣微粉生产中的应用[J].水泥科技,2002(3):20-21.
4张端美,郭宏武.HES高效选粉机及其工艺系统在水泥工业中的应用[J].安徽建材,1996(3):16-21.
5张端美,郭宏武.HES高效选粉机在闭路生料磨系统中的应用[J].建材环保与节能,1996(3):37-40.
6张端美,郭宏武,郑青,何正凯.HES高效选粉机的研究和应用[J].水泥,1991(10):12-17. 被引量：1
7Huang Li,Zhou Yuming,Zhang Yiwei,Li Qingning,Tian Xiaoming (School of Chemistry and Chemical Engineering,Southeast University,Nanjing 211189).Propane Dehydrogenation over PtSnNa Catalyst Supported on La-ZSM-5 Zeolite[J].China Petroleum Processing & Petrochemical Technology,2010,12(3):18-24. 被引量：4
8张珂,柳云骐,赵晋翀,刘晨光.Hierarchical Porous ZSM-5 Zeolite Synthesized by in situ Zeolitization and Its Coke Deposition Resistance in Aromatization Reaction[J].Chinese Journal of Chemistry,2012,30(3):597-603. 被引量：4
9Liu Hui,Zhou Yuming,Zhang Yiwei,Sheng Xiaoli,Zhang Zewu,Zhou Shijiang.Effect of Impregnation Sequence on Propane Dehydrogenation Performance of PtSnNa/ZSM-5 Catalyst[J].China Petroleum Processing & Petrochemical Technology,2013,15(4):54-62. 被引量：1
10刘维桥,雷卫宁,刘平,尚通明,任杰,孙予罕.Zn对Pt/SAPO-11催化剂物化及异构性能影响[J].化学学报,2010,68(18):1781-1786. 被引量：7

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